Method for making an intermediate reinforcing material consisting of an array of spaced-apart yarns/webs

ABSTRACT

The present invention relates especially to an intermediate material comprising, or even constituted exclusively by, an array of individualised ribbons, each ribbon being composed by a tape of unidirectional reinforcing fibres associated, by adhesion, on each of its faces with a veil of thermoplastic fibres, characterised in that the ribbons are disposed in successive layers, in such a way that the ribbons of two successive layers are superposed with or without crossing but without interlacement, the bond between a ribbon and the ribbon or ribbons with which it is superposed being ensured by adhesion, and in that in each layer the ribbons are disposed substantially parallel to each other over at least the major part of their length, while being independent and spaced from each other and in that the ribbons of at least two layers extend in two different directions.

This application is a divisional of application Ser. No. 13/808,440,which was filed on Jan. 4, 2013, and issued as U.S. Pat. No. 9,132,606on Sep. 15, 2015, and which is a 371 of PCT/FR2011/051764, which wasfiled on Jul. 21, 2011.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to the technical field of reinforcingmaterials, adapted to the constitution of composite pieces. Moreprecisely, the invention relates to a novel intermediate materialconstituted by an array of ribbons of unidirectional fibres for makingcomposite pieces, by subsequent injection or infusion of thermosetting,thermoplastic resin, or a mixture of the two, a manufacturing process ofsuch intermediate material, as well as a manufacturing process ofcomposite pieces from such intermediate material, and the resultingcomposite pieces.

2. Description of Related Art

The manufacture of composite pieces or articles, that is, comprising onthe one hand one or more reinforcements or fibrous tapes and, on theother hand, a matrix mainly of thermosetting (<<resin>>) type andcapable of including thermoplastic, can for example be made by aso-called “direct” or “LCM process” (from the English <<Liquid CompositeMoulding>>). A direct process is defined by the fact that one or morefibrous reinforcements are used in the “dry” state (that is, without thefinal matrix), the resin or matrix being used separately, for example byinjection in the mould containing the fibrous reinforcements (“RTMI”process, from the English term Resin Transfer Moulding), by infusionthrough the thickness of the fibrous reinforcements (“LRI” process, fromthe English <<Liquid Resin Infusion>> or process “RFI”, from the English<<Resin Film Infusion>>), or else by manual coating/impregnation byroller or brush on each of the unitary layers of fibrous reinforcement,applied successively to the form.

For the RTM, LRI or RFI processes, in general a fibrous preform of theform of the planned finished article should be made first, then thispreform should be impregnated with resin. The resin is injected orinfused by differential of pressures and temperature, then once theentire quantity of necessary resin is contained in the preform, thewhole is brought to a higher temperature to complete thepolymerisation/reticulation cycle and cause curing.

The composite pieces used in the automobile, aeronautics or navalindustry are in particular subjected to very strict demands, especiallyin terms of mechanical properties. The mechanical properties of thepieces are mainly linked to a parameter which is the volume rate offibres (TVF).

In these sectors, a large number of preforms is made based onreinforcing material, mainly of carbon fibres, especially of theunidirectional type. It is possible to theoretically calculate themaximal volume rate of fibres contained in a unidirectional tape bysupposing two types of arrangements: hexagonal or square. Supposingrespectively an arrangement of hexagonal type and an arrangement ofsquare type, the maximum TVF obtained is respectively 90.7% and 78.5%(An Introduction to Composite Materials, D. Hull, T. W. Clyne, SecondEdition, Cambridge Solid State Science Series, 1996). But in reality itseems difficult to get volumic fractions of fibres over 70% forcomposite pieces. In practice, it is commonly admitted by the expertthat a volume rate of fibres (TVF) of around 60% is standard for makingsatisfactory composite pieces, especially with good reproducibility (S.T. Peters, <<Introduction, composite basics and road map>>, in Handbookof Composites, Chapman & Hall, 1998, p. 1-20 and in particular p. 8).

The resin which is subsequently associated, especially by injection orinfusion, with unidirectional reinforcing tapes during production of thepiece can be thermosetting resin, for example of epoxy type. For properflow through a preform comprising a stack of different layers of carbonfibres, this resin is most often highly fluid, for example with aviscosity of the order of 50 to 200 mPa·s. at infusion/injectiontemperature. The major disadvantage of this type of resin is itsfragility after polymerisation/reticulation, which causes low resistanceto the impact of composite pieces produced.

To resolve this problem, it has been proposed in documents of the priorart to associate unidirectional layers of carbon fibres with a veil ofthermoplastic fibres. Such solutions are especially described in patentapplications or patents EP1125728, US 628016, WO 2007/015706, WO2006/121961 and U.S. Pat. No. 6,503,856. The addition of this veilimproves the mechanical properties in a compression test after impact(CAI), a test currently being used to characterise the resistance ofstructures to impact.

In prior patent applications WO 2010/046609 and WO 2010/061114 theapplicant has also proposed particular intermediate materials comprisinga tape of unidirectional fibres, carbon in particular, associated byadhesion, on each of its faces to a veil of thermoplastic fibres (alsocalled non-woven), as well as their preparation process. Theunidirectional tapes ensuring total cover, for some applicationsespecially for making pieces of substantial thickness, one of thelimitations of this type of intermediate material is its low transversepermeability to resin which will be injected or infused to constitutethe final piece. In this context, a solution has been proposed in patentapplication WO 2010/046609 consisting of making holes extending into thematerial, allowing it to have a given opening factor. This solution canbe used in practice on tapes of width greater than around 20 mm, andpreferentially greater than 50 mm, though is more difficult to implementin the case of threads/tape of lesser widths. Widths of 3.17 mm or 6.35mm are used for example in automatic deposit on existing machines andtherefore present a particular interest.

SUMMARY OF THE INVENTION

The aim of the present invention is to eliminate and/or limit theproblems hereinabove and/or contribute improvements in general. Also,one of the aims of the present invention is to propose a novelintermediate product, adapted to producing composite pieces based onthermosetting or thermoplastic resin, and especially by injection orinfusion of resin which has satisfactory permeability and allows minimaldiffusion times of the resin, even in the case of designing pieces ofconsiderable thickness, for example over 20 mm.

Another aim of the invention is to satisfy this specification whileproposing an intermediate product which is easy to manufacture andadapted to automated processes.

Another aim of the invention is also of propose an intermediate productwhich may be directly made in shape on a mould of form adapted to thepreferred final composite piece and therefore is in the form of apreform.

In this context, the invention relates to the intermediate materials,process and composite pieces such as defined in the claims.

In particular, the intermediate material according to the inventioncomprises, or even is constituted exclusively by, an array ofindividualised ribbons, each ribbon being composed by a closed tape ofunidirectional reinforcing fibres associated on each of its faces with aveil of thermoplastic fibres, the bond between the tape ofunidirectional fibres and the veils of thermoplastic fibres beingensured by adhesion, and especially by at least partial fusion ofthermoplastic fibres, characterised in that the ribbons are disposedside by side in successive layers, and especially in at least fourlayers in such a way that the ribbons of two successive layers aresuperposed with or without crossing but without interlacement, the bondbetween a ribbon and the ribbon or ribbons with which it is superposedbeing ensured by adhesion, and especially by at least partial fusion ofthermoplastic fibres, and in that in each layer the ribbons are disposedsubstantially parallel to each other at least over the major part oftheir length, while being independent and spaced apart from each otherand in that the ribbons of at least two layers extend in two differentdirections.

Various other characteristics of the material according to the inventionare detailed in the claims.

The material according to the invention is designed for making compositepieces by a direct process. Also, the mass of non-wovens, within eachveiled ribbon, represents from 0.1 to 10% and preferably from 3 to 10%of the total mass of each ribbon.

Another aim of the invention is a manufacturing process of anintermediate reinforcing material or of a preform according to theinvention comprising the following steps:

-   -   a) having at least one individualised ribbon, composed by a        closed tape of unidirectional reinforcing fibres associated on        each of its faces with a veil of thermoplastic fibres, the bond        between the tape of unidirectional fibres and the veils being        ensured by at least partial fusion of the thermoplastic fibres,    -   b) disposing such ribbons side by side and in successive layers,        especially in at least four layers, in such a way that the        ribbons of two successive layers are superposed with or without        crossing but without interlacement, and such that in each layer        the ribbons are disposed substantially parallel to each other        over at least the major part of their length, while being        independent and spaced apart from each other, and the ribbons of        at least two layers extend in two different directions,    -   c) ensuring the bond between a ribbon and the ribbon or ribbons        with which it is superposed by at least partial fusion of the        thermoplastic fibres.

Another aim of the invention is a manufacturing process of a compositepiece, characterised in that it comprises the following steps:

-   -   a) having at least one intermediate reinforcing material or a        preform according to the invention,    -   b) optionally stacking different materials as claimed in any one        of the preceding claims and optionally combining them in the        form of a preform,    -   c) adding by infusion or injection a thermosetting and/or        thermoplastic resin,    -   d) consolidating the preferred piece via a        polymerisation/reticulation step following a cycle defined in        temperature and under pressure, followed by cooling.

According to a particular embodiment of the process according to theinvention, the thermosetting resin is added by infusion under pressureless than the atmospheric pressure, especially at a pressure less than 1bar and, for example, between 0.1 and 1 bar.

According to another of its aspects, the invention relates to thecomposite pieces likely to be obtained according to such a process,which especially have a volume rate of fibres (TVF) of 50 to 63%,preferably 53 to 60%.

According to another embodiment, the invention provides a mouldingmaterial comprising a multitude of folds, each fold comprising desribbons of renfort oriented and spaced, the orientation of the ribbonsin a fold differing from the orientation of the ribbons in the adjacentfold, each ribbon comprising a fibrous reinforcing material.

The moulding material can also comprise a bonding material formaintaining the orientation of the ribbons. This bonding material cancomprise a fibrous thermoplastic material.

Various other characteristics will emerge from the following descriptionin reference to the attached diagrams.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1, 2A and 2B schematically show different constructions which canbe presented by an intermediate material according to the invention.

FIG. 2A is a view in partial perspective of a layer of ribbons in abossing zone and FIG. 2B is a partial corresponding plan view.

FIGS. 3A and 3B are schematic sectional views showing the positioningwhich can be taken by ribbons of successive layers oriented in the samedirection, in an intermediate material according to the invention.

FIGS. 4 and 5 are respectively a schematic perspective representation,partially exploded and in section, of a ribbon used within the scope ofthe invention, in which a unidirectional tape is associated with twonon-wovens.

FIG. 6 is a schematic view of a device which can be used for makingcomposite pieces.

FIG. 7 shows the evolution of the resin filling rate when theconfigurations illustrated in FIGS. 3A and 3B are used by the infusionprocess under vacuum.

FIG. 8 represents the evolutions of transverse permeability as afunction of the TVF obtained for materials according to the inventionand comparative materials.

DETAILED DESCRIPTION OF THE INVENTION

The invention proposes materials made by depositing ribbons, some ofwhich at least, and preferably all, are so-called veiled ribbons. Withinthe scope of the invention, the unidirectional threads or filamentsconstituting the ribbons are associated on each of their faces withnon-wovens (also called veils), before their use to constitute theintermediate material according to the invention. Also, in the materialaccording to the invention, each veiled ribbon is constituted by a tapeof unidirectional reinforcing fibres associated with two non-wovens overits entire length. As presented in FIG. 1, within the scope of theinvention, different ribbons 100, 101, . . . 200, 201, . . . 300, 301, .. . are disposed flat side by side and in successive layers 10, 20, 30 .. . , while being spaced apart from each other in each layer by adistance e1, e2, e3 . . . The first series 10 (also called layer orfold) of ribbons is deposited on a plane surface as illustrated in FIG.1 or in the form as illustrated by FIGS. 2A and 2B. A second series 20of ribbons side by side and spaced is then placed flat or shaped, forexample in an orientation different to that of the first series 10. Thenext step is a stack of different series of ribbons parallel to eachother in each series, and preferably of at least four series, as afunction of the thickness and preferred orientations, by analogy with aconventional unidirectional material. All the layers of ribbons can havedifferent directions or only some of them might, the others able to haveidentical directions. The preferred orientations are most often orientedin directions forming an angle of 0°, +45° or −45° (corresponding alsoto +135°), and +90° with the principal axis of the piece to be made. Theprincipal axis of the piece is generally the largest axis of the pieceand the 0° combines with this axis. It is for example possible to makequasi-isotropic or symmetrical stacks or stacks oriented from selectingthe orientation of the folds. By way of example of a quasi-isotropicstack, there are those stacks according to the angles 45°/0°/135°/90°,or 90°/135°/0°/45°. By way of example of symmetrical stacks, there are0°/90°/0°, or 45°/135°/45°. In each series, the ribbons extendsubstantially parallel to each other, except for example in bossingzones 11 where additional bits of ribbons m1, m2 . . . can be positionedbetween strips 100, 101 . . . , creating zones of non-parallelism, asillustrated by FIGS. 2A and 2B. These bits of ribbons are introduced torespect the preferred direction of the threads, but compensate for thedifferences of length due to bossing. The insertion of segments ofribbon is done only in extreme cases. When this is possible, spacingwill be created in curving zones between two strips or series of stripsslightly different comparatively to the inter-strips space present onthe plane zones of the same piece. Consequently, in each layer or fold,the ribbons are positioned parallel to each other over their entirelength, with the exception of curving or bossing zones wherenon-parallelism can be introduced especially due to the difference indistance to be travelled by two adjacent ribbons.

The presence of spacings between two adjacent ribbons within the sameseries increases plane instances of permeability (that is, parallel tothe tapes of fibres) and transverse instances (that is, transversally tothe tapes of threads) of the intermediate material according to theinvention, relative to material where the unidirectional tapes wouldensure total coverage. Especially, within the scope of the inventiontransverse permeability in saturated state of 10⁻¹⁴ m² and 2.10⁻¹⁴ m²can be obtained. For such permeability to be ascertained however, theribbons of two successive layers must be disposed so that there is totalcoverage of the spaces between ribbons of one of the layers by theribbons of the other layer. This is the case especially:

-   -   either when there is no successive layer in which the ribbons        extend in identical directions,    -   or when there are successive layers 40 and 50 in which the        ribbons are oriented in identical directions, but where there is        perfect or quasi-perfect superposition of ribbons of layers in        which the ribbons are oriented in identical directions, as        illustrated by FIG. 3A. In fact, the ribbons 400 and 401 of the        layer 40 are superposed with the ribbons 500 and 501 of the        layer 50. The strips of two successive layers of identical        orientation must not be offset relative to the others, according        to offsetting which would cause total coverage of the        inter-ribbon spaces by the ribbons of the lower or upper layer.

In fact, in the case illustrated in FIG. 3B where the strips of twosuccessive layers are offset by a demi-width of strip such that thespaces of one or the other of the layers coincide with the strips of theother layer, permeability is not improved. All the same, such materialis easy to design, especially for making preforms on moulds shaped,depositing strips of minimal width being easier than depositing sheetmaterial of greater width.

By way of advantage, each layer of ribbons has an opening factorbelonging to the range 0.5 to 9%, preferably 3 to 6%. This openingfactor is the opening factor of each layer taken individually, byabstracting from the other layers. The opening factor is for exampledetermined according to the method described in patent application WO2010/046609 which could be referred to for more details. To undertakethis on a single fold, the deposit could be made on a transparent vacuumtarpaulin, with adhesion occurring in the same way as with a precedingfold constituted by a strip of the same material. Such opening factorsproduce interesting levels of permeability comparable to or greater thanthose obtained with traditional sewn multiaxial fabrics. For example, ineach series (also called layer) of parallel ribbons, the width ofribbon/spacing ratio between two adjacent ribbons belongs to the rangegoing from 7 to 150, preferentially to the range going from 15 to 40.Most often, in each layer, or even in all layers of ribbons, all theribbons will have a substantially identical width and the spaces (e1,e2, e3, e4, e5 . . . as shown in FIGS. 1, 3A and 3B) between twoadjacent ribbons will also be substantially identical. In addition, itis preferable for the spacing between two adjacent ribbons within alayer in the parallelism zones to be at most 0.4 mm to avoid thecreation of resin piles during the design of the final piece, whichwould be especially a source of microcracking after hygrothermal cycle.This spacing value corresponds to an average on the parallelism zones.This spacing belongs for example to the range going from 0.1 to 0.4 mm,preferably to the range going from 0.2 to 0.4 mm. All the same, it ispossible in the zones of curving or of bossing where the ribbons arelocally non-parallel (called zones of non-parallelism) for theinter-ribbon space to be slightly larger.

The ribbons of the same series or layer are individual from andindependent of one another, as compared especially to ribbons ofunidirectional fibres which would be connected together by one and thesame veil. The ribbons of the same series are connected solely by thepresence of ribbons of other layers crossing them and ensuring the bondof the array. The bond of the array is ensured by the bond between aribbon and the ribbon or ribbons with which it is superposed, this bondbeing made by adhesion. To ensure cohesion of the array, at least twolayers of ribbons have different orientations. This bond is most oftenmade by at least partial fusion of the thermoplastic fibres comprisingthe veils, followed by cooling. This fusion can be ensured throughoutthe depositing of each veiled ribbon, by analogy with the processdescribed in patent application EP 1 469 113 in the name of theapplicant, or in a thermo-compression step on one or more complete foldsor over part of their surface only, for example on the external parts ofthe pieces to be made, for example their periphery, on a support ofplane or more complex form. The fusion can also be ensured flat on apart of the form to be made, this fusion between folds being carried outparticularly on those zones not needing movement between folds duringthermo-compression, the rest of the folds remaining free of any movementby enabling all folds to be made shaped by movement of the threads fromfolds remaining unattached to lower folds. It is also not excluded thatthe veils are covered by another polymeric binder, for example athermosetting powder, of epoxy type especially, which would ensure orcontribute to the bond. There is preferably no bond between thedifferent layers of ribbons done by sewing and/or knitting.

Another advantage of the material according to the invention made fromindividual and independent strips constituted by unidirectionalreinforcing fibres associated on each of their faces with a non-woven ofthermoplastic fibres is found especially at the level of deformability,and ease of preform design on moulds of complex shape. In fact, directlyusing ribbons carrying non-wovens, which will contribute the preferredmechanical properties to the final piece, offers numerous designpossibilities. For example, the material according to the invention canbe obtained directly by deposit of veiled ribbon on a flat support orshaped according to the preferred form of the piece. The materialaccording to the invention can be made shaped directly, the shape beingmaintained due to fusion/cooling of the thermoplastic fibres, or in aplane sheet which could then be positioned and draped, after lightheating, over a mould of complex shape, during design of the finalpiece.

Within the scope of the invention, ribbon or strip means sheet materialwhich has a length much greater than its width. Such ribbons canespecially have widths of 3 to 25 mm. The veiled ribbons can be madefrom one or more threads, a thread being constituted by an array offilaments. Voiles ribbons of lesser width can even be obtained in thecase where a very fine thread of 1K or 3K is used. As shown in FIG. 4,the veiled ribbons I used within the scope of the invention have alength l and a width L. These veiled ribbons comprise an array offilaments f (case of a single thread 1) or an array of threads 1 (eachconstituted by an array of filaments) which extend parallel to the widthof the ribbon. A veiled ribbon has a general rectangular shape and isassociated on each of its large faces 1 a and 1 b with a non-woven(respectively 2 a and 2 b), as shown in FIG. 5.

Non-woven, which can also be called <<veil>>, conventionally means a matof continuous or short fibres arranged randomly. These non-wovens orveils could be produced for example by the <<Meltblow>>, <<Spunlaid>> or<<Electrospinning>> processes well known to the expert. In particular,the fibres making up the non-woven can have average diameters in therange going from 0.5 and 70 μm, and preferentially from 0.5 and 30 μm.The non-wovens can comprise short fibres or preferably continuousfibres. In the case of a non-woven of short fibres, the fibres can havea length between 1 and 100 mm, for example. The use of non-wovens whichhave random and isotropic coverage gives each veiled ribbon uniformcohesion and in all directions, contrary to using threads of spacedbond, for example. For each veiled ribbon, the bond between thenon-wovens and the unidirectional tape has been previously ensured, byheating, in using the hot-adhesive character of thermoplasticnon-wovens, followed by cooling. By way of example, the fibresconstituting non-wovens are advantageously constituted by thermoplasticmaterial, especially selected from: Polyamides (PA, for example PA6,PA12, PA11. PA6,6, PA 6,10, PA 6,12, . . . ), Copolyamides (CoPA),Polyamides—block ether or ester (for example, PEBAX, PEBA),polyphthalamide (PPA), Polyesters (for example, Polyethyleneterephthalate—PET-, Polybutylene terephthalate—PBT- . . . ),Copolyesters (CoPE), polyurethanes thermoplastic (TPU), polyacetals(POM), Polyolefins in C2-C8 (for example, polypropylenes—PP,high-density polyethylenes—HDPE, low-density polyethylenes—LDPE,low-density linear polyethylenes—LLDPE . . . ) and/or copolymers of thelatter, Polyethersulfones (PES), polysulfones (PSU), polyphenylenesulfones (PPSU), Polyetheretherketones (PEEK), PolyetherKetoneKetone(PEKK), Poly(phenylene sulfide) (PPS), or Polyetherimides (PEI),thermoplastic polyimides, liquid crystal polymers (LCP), phenoxys, blockcopolymers such as Styrene-Butadiene-Methylmethacrylate (SBM)copolymers, Methylmethacrylate-Acrylate of Butyl-Methylmethacrylate(MAM) copolymers and their mixtures. The non-wovens can comprise fibresof the same type, but also a mixture of fibres constituted by thesethermoplastic materials. The substance is adapted of course to differenttypes of thermosetting or thermoplastic systems used to constitute thematrix, during subsequent production of the composite pieces.

Each veiled ribbon used for the constitution of the intermediatematerial according to the invention has, on each of its large faces, anon-woven of thermoplastic fibres which ensures its cohesion. Inparticular, by way of non-woven of thermoplastic fibres, non-wovensmarketed for example by the companies Protechnic (66, rue des Fabriques,68702—CERNAY Cedex—France) or Spunfab Ltd./Keuchel Associates, Inc. (175Muffin Lane Cuyahoga Falls, OH 44223, USA) can be used.

Within the scope of the invention, << unidirectional tape of reinforcingfibres >> means a tape exclusively or quasi-exclusively comprisingreinforcing fibres deposited parallel to each other. In particular,according to a particular embodiment of the invention, theunidirectional tape comprises no weft thread interlacing the reinforcingfibres to avoid any undulation. In particular, the intermediate materialaccording to the invention comprises neither weaving, nor sewing, norknitting. In the unidirectional tape, the carbon threads are preferablynot associated with a polymeric binder and therefore qualified as dry,that is, they are neither impregnated, nor coated, nor associated withany polymeric binder before being joined to the thermoplastic veils. Thecarbon fibres are, however, most often characterised by a standard massyarning rate which can represent at most 2% of their mass.

Unidirectional tapes can comprise one or more reinforcing threads. Byway of example, the reinforcing threads can be made of material selectedfrom the following materials: carbon, glass, aramid, silica, basalt,ceramic and their mixtures, or any other material used in the compositematerials field, the fibres able to be natural or synthetic. Carbonfibres are preferred, however.

Within each ribbon the filaments or reinforcing fibres are disposed toensure a quasi-total coverage, and preferably total, over the entiresurface of the ribbon. In particular, when the veiled ribbon isconstituted by a unidirectional tape of several threads, these will bearranged edge to edge, with a minimum, or any lack of material (<<gap>>in English) or overlap (<<overlap>> en English). The unidirectional tapeand therefore the veiled ribbon used can therefore be qualified asclosed.

A thread is generally constituted by an array of filaments and in thecase of carbon threads comprises generally from 1000 to 80,000filaments, advantageously from 12,000 to 24,000 filaments. In aparticularly preferred manner within the scope of the invention, carbonthreads of 1 to 24 K, for example, 3K, 6K, 12K or 24K, andpreferentially 12 and 24K, are used. The constituent fibres arepreferably continuous. The threads present within the veiled ribbonshave a substantially parallelepipedic or elliptical cross-section andare qualified as flat threads. These threads have a certain width andthickness. By way of example, a flat carbon thread of 3K and yarndensity of 200 tex generally has a width of 1 to 3 mm, a flat carbonthread of 12K and yarn density of 446 tex, a width of 2 to 5 mm, a flatthread of 12K yarn density of 800 tex, a width between 3 and 7 mm, aflat carbon thread of 24K and yarn density of 1600 tex, a width of 5 to12 mm and a flat carbon thread of 24K and yarn density of 1040 tex, awidth of 5 to 10 mm. A flat carbon thread of 3000 to 24,000 filamentswill therefore most often have a width of 1 to 12 mm. For someembodiments, the carbon threads present within the veiled ribbons have adensity of between 60 and 3800 tex, and preferentially between 400 and900 tex. Before the thread or threads are joined to the veils to makethe ribbons, it is possible to spread out threads used conventionallyand commercially available or not. By way of example, the thickness ofthe unidirectional tape of carbon within a ribbon can be from around 90to 270 μm. Examples of carbon threads are High-Resistance (HR) threadswhereof the tensile modulus is between 220 and 241 GPa and whereof thetensile breaking strength is between 3450 and 4830 MPa, IntermediateModulus (IM) threads whereof the tensile modulus is between 290 and 297GPa and whereof the tensile breaking strength is between 3450 and 6200MPa and the High-Modulus (HM) threads whereof the tensile modulus isbetween 345 and 448 GPa and whereof the tensile breaking strength isbetween 3450 and 5520 Pa (according to the <<ASM Handbook>>, ISBN0-87170-703-9, ASM International 2001).

The veiled ribbons such as previously described, and some more specificexamples of which will be given, throughout the description and theexamples, are used within the scope of the invention to manufactureintermediate materials, intended to be associated with a resin matrixfor subsequent production of composite pieces, for aeronauticsespecially. The resin matrix can be thermoplastic or preferablythermosetting in nature or comprising a mixture of thermosetting andthermoplastic resins. In the intermediate materials according to theinvention, these veiled ribbons are disposed side by side to leavespacing between two adjacent ribbons. Each array of ribbons depositedsubstantially parallel to each other is called a layer. To constitutethe intermediate material, different layers, and most often at leastfour layers, are superposed and optionally criss-crossed withoutinterlacement. The intermediate materials according to the inventionpreferably and exclusively comprise veiled ribbons composed of a seriesof reinforcing threads or filaments which extend in a direction parallelto the length of the ribbon to form a unidirectional tape which isassociated on each of its faces with a non-woven of thermoplasticfibres, these two non-wovens ensuring cohesion of said veiled ribbon dueto their thermoplastic character. In particular, intermediate materialsaccording to the invention are exclusively constituted by an array ofveiled ribbons such as described more specifically in the present patentapplication. It is not however excluded that in the intermediatematerials according to the invention these veiled ribbons are combinedwith other ribbons such as single threads or other. In fact, theseveiled ribbons can for example be used only in some orientations of amultiaxial material, the threads of other orientations being classic andnot veiled, or even being constituted exclusively or not by other typesof dry reinforcements such as a braid, a fabric or a sewn multiaxial.

Patent applications WO 2010/046609 and WO 2010/061114, to whichreference could be made for more details, describe particular types ofveiled ribbons of carbon fibres which produce intermediate materialsaccording to the invention, which especially will subsequently makecomposite pieces which at the same time will combine good mechanicalproperties and a high volume rate of fibres, preferred propertiesespecially in the aeronautics field. According to a preferredembodiment, each veiled ribbon making up the intermediate materialaccording to the invention is constituted by a unidirectional tape ofcarbon fibres having a surface mass of 100 to 280 g/m2, associated oneach of its faces with a non-woven of thermoplastic fibres, saidnon-wovens each having a thickness of 0.5 to 50 microns, preferably of 3to 35 microns. According to a particular embodiment, each veiled ribbonhas a thickness of 80 to 380 microns, preferably of 90 to 320 microns,and preferentially of 93 to 305 microns. Within the scope of the presentinvention, the thicknesses and the grammages are determined for exampleaccording to the techniques described in patent application WO2010/046609.

Advantageously, the thickness of each veiled ribbon present within theintermediate product according to the invention has low variability,especially with variations in thicknesses not exceeding 20 μm in termsof standard deviation, preferably not exceeding 10 μm in terms ofstandard deviation. This characteristic improves the regularity ofcomposite pieces which can be obtained.

In addition, the surface mass of the veil present within each veiledribbon is advantageously in the range going from 0.2 to 20 g/m².

In each ribbon, the association between the unidirectional tape and theveils can be made discontinuous, for example solely at some points orzones, but is preferably done according to a bond qualified ascontinuous, which extends over the entire surface of the tape. Theassociation of the unidirectional tape with the two veils can beachieved by means of an adhesive layer, for example selected fromepoxide adhesives, polyurethane adhesives, thermosetting adhesives,adhesives based on polymerisable monomers, structural acrylic ormodified acrylic adhesives, hot-melt adhesives. But most often theassociation is made due to the adhesive character of hot veils, forexample during a thermocompression step when they are designed, ensuringa bond between the unidirectional tape and the veils. The bond istherefore most often, at least in part, ensured by at least partialfusion of the thermoplastic fibres of the veils, followed by cooling. Asis preferred, the cohesion of each veiled ribbon is ensured in theabsence of sewing, weaving or knitting. Advantageously, the bond betweenthe unidirectional tape and the veils is ensured exclusively by thethermoplastic non-wovens.

According to a particular embodiment, each veiled ribbon has a givenwidth substantially constant over its entire length, that is, the veiledribbons have very low variability in width over their entire length. Inthis case, because of the substantially constant width of the veiledribbons used, the veiled ribbons according to the invention also havevery low variability in terms of surface mass. In particular, the widthof each veiled ribbon has, over the entire length of said ribbon, a typeof deviation especially less than 0.25 mm, preferably less than 0.22 mmand preferentially less than or equal to 0.20 mm. Low variability inwidth especially subsequently produces pieces with considerableregularity, with controlled mechanical properties. The width of theveiled ribbons and the deviation type can be determined according to themethod given in patent application WO 2010/061114. Such a veiled ribbonof substantially constant width can be obtained according to the processdescribed in patent application WO 2010/061114, which could be referredto for more details.

According to a particular embodiment which can be combined with thepreceding ones, each veiled ribbon has no cut fibres on its longitudinaledges. This makes the use of the latter much easier in automatic depositprocesses. In fact, the disadvantage of the presence of fibres orfilaments cut at the edge of a ribbon is to create accumulation zones offibres or filaments T some points along the trajectory of the ribbon inthe processes cited, and cause machine stoppages due to thread breaks orpoor quality of the reinforcement created. These edges with presence ofcut filaments are also generators of threads rolling up on themselveseven during unwinding of the spool containing the ribbon, theconsequence of which is also thread breaks or quality defects (such as<<rings>> created on the ribbon spool). Such a characteristic is madepossible especially by the process previously described in patentapplication WO 2010/061114.

Also, according to a particular embodiment which can be combined withthe preceding ones, each veiled ribbon has at some points only of itslongitudinal edges or over the entire length of its two longitudinaledges a direct bond between the two non-wovens, achieved due to thethermoplastic character of the latter.

The intermediate materials according to the invention can be used formaking aeronautics articles which require high levels of mechanicalperformance, and especially for making pieces of primary structure, butalso for the design of pieces in the fields of automobiles, windturbines, high-pressure reservoirs or other industrial applicationswhere the mechanical characteristics do not have the same importance butwhere the intermediate product according to the invention could berelevant in terms of speed of diffusion of the resin injected or infusedsubsequently. Such pieces could be made by any known direct process,such as processes by infusion or injection of thermosetting or eventhermoplastic resins. The matrix used is preferably of thermosettingtype. The injected resin will be selected for example from the followingthermosetting polymers: epoxides, unsaturated polyesters, vinyl esters,phenolics, polyimides, bismaleimides. The composite piece is obtainedafter a thermal processing step. In particular, the composite piece isgenerally obtained by a cycle of classic consolidation of relevantpolymers by conducting thermal processing, recommended by the suppliersof these polymers and known to the expert. This consolidation step ofthe preferred piece is carried out by polymerisation/reticulationfollowing a cycle defined in temperature and under pressure, followed bycooling. The pressure applied during the processing cycle is low in thecase of infusion under vacuum and is stronger in the case of injectionin a RTM mould.

In some cases, the intermediate material and the process according tothe invention produce composite pieces having a TVF of the order of 60%,which corresponds to the standard rate for primary structures inaeronautics (that is, the vital pieces for the apparatus) and alsodefinitively produce resistance to low-speed impact of the resultingcomposite pieces: for example, the a tool falling in a workshop duringmanufacture of a composite structure, shock from a foreign body whenused as a ground-based operation.

The pressure applied during an injection process is greater than thatused during an infusion process. Also, injection processes generally useclosed moulds, resulting in greater ease in making pieces with a correctTVF via a process of injection or infusion. The materials according tothe invention create the preferred volume rate of fibres, and especiallyof the order of 53 to 60%, even when the composite piece is made with astep c) such as mentioned previously, which uses infusion and notinjection of resin. Such an embodiment also constitutes an advantageousvariant, especially in terms of overall cost for manufacturing acomposite piece.

The composite pieces likely to be obtained according to the process ofthe invention also for integral parts of the invention, in particularpieces which have a volume rate of fibres of 50 to 63% and especially of53 to 60%.

The examples hereinbelow illustrate the invention, without having alimiting character.

Exemplary Embodiments

Description of Starting Materials

The material used for these assays is the following:

Sheet of 3 carbon threads IMA 12K, 446Tex, of the company Hexcel,associated with a thermoplastic veil 128D06 of the company Protechnic oneach side.

The tape is calibrated in width to 5.97 mm (deviation type: 0.16 mm)according to the process described in patent application FR08 58096,using the following settings:

T veil preheating T bars (° C.) Line speed T bar (° C.) T bar (° C.) (°C.) (11a (12a and (m/min) (9) (10) and 11b) 12b) 1.3 257 257 160 180

The final grammage of the resulting ribbon is 224 g/m².

Process Used for Depositing the Ribbons:

Automatic contact application, ribbon by ribbon, was carried out by ahead which guarantees that the thread is held during deposit byeliminating any lateral movement.

The application head of reinforcing threads on a deposit surfacecomprises:

-   -   A support structure composed of a support plate delimiting a        front face and a rear face on both sides. The motor elements are        supported by the rear face which is provided with passages for        the axes of transmission so that the functional elements are        located to the side of the front face of the support plate.    -   A guide device to the application zone, of at least one        reinforcing thread coming from a storage device. This device is        borne by the front face.    -   An applicator element of roller type mounted on a shifting        device for applying pressure on the reinforcing thread in        contact with the deposit surface.    -   A system for heating reinforcing threads closest to the        application zone.    -   A mechanism for cutting reinforcing threads upstream of the        application zone on the deposit surface, this mechanism        comprising at least one cutting element and a motor element (of        rotating type) for shifting cutting element on the one hand,        according to an out course for enabling cutting of the        reinforcing threads and on the other hand, according to a return        course for enabling disengagement of the cutting element        relative to the reinforcing threads. The cutting mechanism        comprises an anvil on which the cutting element ensures cutting        of the reinforcing threads.    -   A redirection system of the reinforcing threads after being cut,        at least as far as the application zone, this redirection system        comprising motorisation (of rotating type).    -   A mechanism for tightening the reinforcing threads controlled by        displacement by a rotating motor element mounted on the rear        face of the support plate.

This head is mounted on a robot M16ib by the company FANUC, said robothaving capacities for the precision and reproducibility necessary forthe precise depositing such as described. Each ribbon is deposited flat,the deposit being done by heating the preceding fold by means of ahot-air pistol of the brand LEICESTER, model LE Mini Sensor, version800W. The air inlet rate is 25 liters per minute, a burst at a rate of11 liters per minute being created after heating. The inlet pressure isapproximately equal to 0.2 bar, and the deposit speed is 30 mm/s. Thedistance between the hot-air exit nozzle and the heated fold is around 5mm such that the deposit is done smoked, that is, without degrading theyarning of the carbon threads of the tape and of the preceding fold andwith satisfactory adhesion. The support of the placing roller on thesurface, whether comprising for example a plastic film or strips ofcarbon already deposited constituting the preceding fold, is translatedby a force located in the range 700 cN to 900 cN.

The first fold, due to the absence of the preceding fold, has beendeposited in the same way without heat, the ends of the ribbons beingstuck by double-sided Scotch at their end on around 20 mm, the depositalways being automatic.

Eight folds have been deposited for each preform according to aquasi-isotropic stack (45°, 0°, 135°, 90°, 90°, 135°, 0°, 45°).

Four preforms of a size of 305×305 mm have been made. The first withoutspace between the deposited ribbons, the second with a space of 0.2 mmbetween two adjacent deposited ribbons, the third with a space of 0.4 mmbetween two adjacent ribbons deposited with exact superposition of theribbons in the two folds oriented at 90° and the fourth with a space of0.4 mm between two adjacent ribbons deposited with offsetting of asemi-width of ribbon in the two folds oriented at 90°.

Characteristics of the Preforms and/or the Resulting Pieces.

Several preforms of 8 folds have been made, the latter having undergonethe following tests:

-   -   Weighing of the preform of 8 folds to determine the mass by        folds and calculate the Volume Fibre Rate (TVF) before and after        infusion and baking,    -   Measuring thickness of the preform under 1 mbar of residual        pressure for measuring the TVF,    -   Infusion with the resin RTM6 by Hexcel, followed by the baking        cycle prescribed by the product record, and thickness        measurement to deduce the TVF,    -   Recording of the quantity of resin entering the preform as a        function of time,    -   Measuring of the transverse permeability of each preform        according to the method described in patent application WO        2010/046609. Transverse permeability can be defined by the        aptitude of fluid to pass through fibrous material in the        transverse direction, therefore outside the plane of the        reinforcing. It is measured in m². The values given hereinabove,        as well as those mentioned in the following examples, are        measured with the apparatus and measuring technique described in        the thesis entitled <<Problematic of measuring transverse        permeability of fibrous preforms for the manufacture of        composite structures>>, by Romain Nunez, defended at the Ecole        Nationale Superieure des Mines de Saint Etienne, on Oct. 16        2009, to which reference on could be made for more details. The        measuring is especially conducted with control of the thickness        of the sample during the test by using two co-cylindrical        chambers to reduce the influence of <<race-tracking>> (passage        of fluid to the side or <<on the side>> of the material whereof        the permeability is to be measured). The fluid used is water and        the pressure is 1 bar+/−0.01 bar. This test needed three        preforms of each type to be made.

Volume rate of fibre preform Volume rate of Final surface Example underreduced fibre panels mass per Space between pressure (4 infused undermeasured threads mBar residual) reduced pressure fold Comparative 59%60.70% 226 g/m² Example 1 None Ex. 1 58% 59.70% 219 g/m² 0.2 mm withsuccessive superposed folds at 90° without offsetting Ex. 2 53.50%  58.70% 209 g/m² 0.4 mm h successive folds at 90° superposed withoutoffsetting Ex. 3 56%  59.1% 209 g/m² 0.4 mm with successive folds at 90°superposed with offsetting of ½ space

Each individual fold has an opening factor of 0.2×100/(5.98+0.2)=3.2%(Ex1); 0.4×100/(5.98+0.4)=6.3% (Ex2, Ex3), and 0% for ComparativeExample 1.

Infusion Technique

Infusion of the resin is done, by using a device such as shown in FIG.6, in which the following references are used:

I: preform, 600: metal base plate, 601: vacuum bag, 602: semi-permeablemembrane, 603: non-woven. 604: Scotch tape, 605: peel ply, 606: materialof diffusion, 607: resin inlet, 608: resin outlet vacuum outlet, 609:vacuum line.

Infusion Procedure:

-   -   Prepare the vacuum bag by ensuring to seal the edges of the        preform to guarantee pure transverse infusion,    -   Heat the assembly to 100° C. in an enclosure,    -   Apply the maximum vacuum (1 mbar residual) on the vacuum outputs        and in the vacuum bag,    -   Open the resin inlet previously heated to 80° C.,    -   When the preform is filled with resin, close the resin inlet and        outlet by leaving the vacuum on the vacuum line above the        membrane,    -   Increase the temperature to 180° C.,    -   Maintain the maximum vacuum (1 mbar residual) in the vacuum bag,    -   Wait for completion of baking and release the piece from the        mould.        Example of Filling of Preforms During Infusion        The graph presented in FIG. 7 shows that:    -   The preform in which the superposed ribbons of the two        successive folds in the same orientation at 90° are perfectly        aligned without offsetting very easily lets the resin return as        a function of time.    -   The preform in which the superposed ribbons of the two        successive folds in the same orientation at 90° are offset by a        semi-width of ribbon let only very little resin return as a        function of time. This is explained by the fact that the        channels created by the spaces between ribbons are stopped and        therefore no longer allow the resin to run out between the        folds.        Measurements of Permeability

In FIG. 8, each curve is the average of three measurements. Eachmeasurement has been made on a preform a single time.

The results presented in FIG. 8 show that the preforms made bysuccessive deposits of ribbons spaced with spaces between ribbons of 0.4and 0.2 mm for tapes of 5.97 mm of 226 g/m² are more permeable thanSerge fabric 2/2 of 300 g/m² considered as the reference in the range55-60% of TVF (Comparative Example 2). In this example, a preform offour folds of fabric 48302 (Hexcel reference) has been draped in a stack0/90, 45/135, 0/90, 45/135. By comparison, the permeability of a preformin which the superposed ribbons of two successive folds in the sameorientation at 90° are offset by a semi-width of ribbon is identical tothe permeability of a preform made without space between veiled ribbons.

The invention claimed is:
 1. A method for making an intermediatematerial comprising a preform made up of multiple layers of veiledribbons, said preform having a principal axis and wherein said methodcomprises the steps of: providing a first layer comprising first veiledribbons that are oriented parallel to each other in a first angulardirection with respect to said principal axis, said first veiled ribbonseach comprising a layer of first unidirectional fibers and a veil ofthermoplastic located on a first side of said layer of firstunidirectional fibers and a veil of thermoplastic located on a secondside of said layer of first unidirectional fibers, said first veiledribbons each comprising edges that define the widths of said firstveiled ribbons wherein said first veiled ribbons are spaced apart insaid first layer to provide first linear gaps between said first veiledribbons that are adjacent to each other; providing a second layercomprising second veiled ribbons that are oriented parallel to eachother in said first angular direction with respect to said principalaxis, said second veiled ribbons each comprising a layer of secondunidirectional fibers and a veil of thermoplastic located on a firstside of said layer of second unidirectional fibers and a veil ofthermoplastic located on a second side of said layer of secondunidirectional fibers, said second veiled ribbons each comprising edgesthat define the widths of said second veiled ribbons wherein said secondveiled ribbons are spaced apart in said second layer to provide secondlinear gaps between said second veiled ribbons that are adjacent to eachother; bonding said second layer to said first layer so that the firstside of said layer of first unidirectional fibers is adjacent to thefirst side of said layer of second unidirectional fibers, said firstveiled ribbons and said second veiled ribbons being superposed over eachother so that said first linear gaps are aligned with said second lineargaps; providing a third layer comprising third veiled ribbons that areoriented parallel to each other in a second angular direction withrespect to said principal axis, said second angular direction beingdifferent from said first angular direction, said third veiled ribbonseach comprising a layer of third unidirectional fibers and a veil ofthermoplastic located on a first side of said layer of thirdunidirectional fibers and a veil of thermoplastic located on a secondside of said layer of third unidirectional fibers, said third veiledribbons each comprising edges that define the widths of said thirdveiled ribbons wherein said third veiled ribbons are spaced apart insaid third layer to provide third linear gaps between said third veiledribbons that are adjacent to each other; bonding said third layer tosaid first layer so that the second side of said layer of firstunidirectional fibers is adjacent to the first side of said layer thirdunidirectional fibers; providing a fourth layer comprising fourth veiledribbons that are oriented parallel to each other in a third angulardirection with respect to said principal axis, said third angulardirection being different from said first angular direction and saidsecond angular direction, said fourth veiled ribbons each comprising alayer of fourth unidirectional fibers and a veil of thermoplasticlocated on a first side of said layer of fourth unidirectional fibersand a veil of thermoplastic located on a second side of said layer offourth unidirectional fibers, said fourth veiled ribbons each comprisingedges that define the widths of said fourth veiled ribbons wherein saidfourth veiled ribbons are spaced apart in said fourth layer to providefourth linear gaps between said fourth veiled ribbons that are adjacentto each other; bonding said fourth layer to said third layer so that thesecond side of said layer of third unidirectional fibers is adjacent tothe first side of said layer of fourth unidirectional fibers; providinga fifth layer comprising fifth veiled ribbons that are oriented parallelto each other in a fourth angular direction with respect to saidprincipal axis, said fourth angular direction being different from saidfirst angular direction, said fifth veiled ribbons each comprising alayer of fifth unidirectional fibers and a veil of thermoplastic locatedon a first side of said layer of fifth unidirectional fibers and a veilof thermoplastic located on a second side of said layer of fifthunidirectional fibers, said fifth veiled ribbons each comprising edgesthat define the widths of said fifth veiled ribbons wherein said fifthveiled ribbons are spaced apart in said fifth layer to provide fifthlinear gaps between said fifth veiled ribbons that are adjacent to eachother; bonding said fifth layer said second layer so that the secondside of said layer of second unidirectional fibers is adjacent to thefirst side of said layer of fifth unidirectional fibers; providing asixth layer comprising sixth veiled ribbons that are oriented parallelto each other in a fifth angular direction with respect to saidprincipal axis, said fifth angular direction being different from saidfirst angular direction and said fourth angular direction, said sixthveiled ribbons each comprising a layer of sixth unidirectional fibersand a veil of thermoplastic located on a first side of said layer ofsixth unidirectional fibers and a veil of thermoplastic located on asecond side of said layer of sixth unidirectional fibers, said sixthveiled ribbons each comprising edges that define the widths of saidsixth veiled ribbons wherein said sixth veiled ribbons are spaced apartin said sixth layer to provide sixth linear gaps between said sixthveiled ribbons that are adjacent to each other; and bonding said sixthlayer to said the fifth layer so that the second side of said layer offifth unidirectional fibers is adjacent to the first side of said layerof sixth unidirectional fibers.
 2. The method for making an intermediatematerial as set forth in claim 1 wherein said first layer, second layer,third layer, fourth layer, fifth layer and sixth layer each has anopening factor that is within the range of from 0.5 to 9%.
 3. The methodfor making an intermediate material as set forth in claim 1 wherein theratio between the widths of said first veiled ribbons and said firstlinear gaps is in the range of from 7 to
 150. 4. The method for makingan intermediate material as set forth in claim 1 wherein the ratiobetween the widths of said second veiled ribbons and said second lineargaps is in the range of from 7 to
 150. 5. The method for making anintermediate material as set forth in claim 1 wherein the ratio betweenthe widths of said third veiled ribbons and said third linear gaps is inthe range of from 7 to
 150. 6. The method for making an intermediatematerial as set forth in claim 1 wherein the ratio between the widths ofsaid fourth veiled ribbons and said fourth linear gaps is in the rangeof from 7 to
 150. 7. The method for making an intermediate material asset forth in claim 1 wherein the ratio between the widths of said fifthveiled ribbons and said fifth linear gaps is in the range of from 7 to150.
 8. The method for making an intermediate material as set forth inclaim 1 wherein the ratio between the widths of said sixth veiledribbons and said sixth linear gaps is in the range of from 7 to
 150. 9.The method for making an intermediate material as set forth in claim 1wherein the total mass of all of the veils of thermoplastic present insaid preform represents from 0.1 to 10% of the total mass of thepreform.
 10. The method for making an intermediate material as set forthin claim 1 wherein the first unidirectional fibers, secondunidirectional fibers, third unidirectional fibers, fourthunidirectional fibers, fifth unidirectional fibers and sixthunidirectional fibers are selected from the group of fibers consistingof carbon, glass, aramid, silica, ceramic fibers and their mixtures. 11.The method for making an intermediate material as set forth in claim 1wherein each of the veils of thermoplastic have a surface mass in therange going from 0.2 to 20 g/m².
 12. The method for making intermediatematerial as set forth in claim 11 wherein said layer of firstunidirectional fibers, said layer of second unidirectional fibers, saidlayer of third unidirectional fibers, said layer of fourthunidirectional fibers, said layer of fifth unidirectional fibers andsaid layer of sixth unidirectional fibers each comprises aunidirectional tape of carbon fibers having a surface mass of 100 to 280g/m².
 13. The method for making intermediate material as set forth inclaim 1 wherein said first veiled ribbons, said second veiled ribbons,said third veiled ribbons, said fourth veiled ribbons, said fifth veiledribbons and said sixth veiled ribbons each has a thickness of 80 to 380microns.
 14. The method for making intermediate material as set forth inclaim 13 wherein the thickness of 80 to 380 microns has a lowvariability such that variations in the thickness do not exceed 20microns in terms of standard deviation.
 15. The method for makingintermediate material as set forth in claim 1 which includes theadditional step of applying a thermosetting and/or thermoplastic resinto said preform.
 16. The method for making intermediate material as setforth in claim 1 wherein said first angular direction with respect tosaid principal axis is 90° and wherein said second angular directionwith respect to said principal axis is 135°.
 17. The method for makingintermediate material as set forth in claim 16 wherein said thirdangular direction with respect to said principal axis is 0°.
 18. Themethod for making intermediate material as set forth in claim 17 whereinsaid fourth angular direction with respect to said principal axis is135°.
 19. The method for making intermediate material as set forth inclaim 18 wherein said fifth angular direction with respect to saidprincipal axis is 0°.
 20. The method for making intermediate material asset forth in claim 19 which includes the additional step of applying athermosetting and/or thermoplastic resin to said preform.